Effect of Cytokinin 4-PU-30 on the Lipid Composition of Water Stressed Bean Plants

Fourteen days-old bean plants, grown on sand with Knop's nutrient solution were subjected to water stress (three days without irrigation). The stress led to a decrease in almost all lipid classes except phospholipids in the primary leaves. The content of palmitic acid increased, and that of the linolenic acid decreased. An increase of hexadecenoic acid in phospholipids was also observed. Rewatering for 24 h led to the recovery of the stressed plants including that of the photosynthetic apparatus, but the changes in the lipid composition were insignificant. The spraying of the plants before and after the water stress with 5 × 10-6 M solution of the phenylurea cytokinin 4-PU-30 alleviated negative effect of water stress on the lipid membrane composition permitting the plants to resist the harmful environment. This revised version was published online in July 2006 with corrections to the Cover Date.     

Production of Transgenic Kidney Bean Shoots by Electroporation of Intact Cells

We obtained transformed bean shoots by electroporation of intact bean cells with the plasmid pDPG165 containing bar gene conferring herbicide resistance to plants. Transformed shoots were selected from electroporated callus on herbicide containing media. Data of molecular analysis (PCR and Southern blotting) confirmed the insertion of bar gene in the genome of herbicide resistant shoots. Detailed procedures for obtaining regenerative bean callus, optimization of electroporation of intact cells and transgenic shoots are given.     

Gibberellic Acid Treatment Reduces the Tolerance of Field-Grown Common Bean to Leaf Removal

I studied the influence of gibberellic acid (GA₃) treatment in a field population of common bean on plant tolerance to leaf removal. Individual bean seedlings were treated with a foliar application of 10 μM GA₃ on day 7 and day 14 after emergence, which led to a significant increase in height in GA₃-treated plants. Twenty-eight days after emergence, either zero, one, two, or three leaflets from each trifoliate leaf were removed from each of 20 GA₃-treated and 20 control plants. All pods were harvested from each plant after plants became senescent 6 weeks later. Multivariate analyses revealed that leaf removal produced significant reductions in several yield components in both GA₃-treated and control plants, although the effects were not pronounced until at least two leaflets from each trifoliate leaf (67% of the total leaf area) were removed. However, GA₃-treated plants suffered greater reductions in total pod wall mass and total seed number than control plants after 33 and 67% leaf area removal. These results indicate that GA₃ treatment may have altered the assimilatory capacity or resource allocation pattern of treated plants in such a way as to decrease their ability to tolerate leaf removal, a negative consequence of the hormonal alteration of traits important to plant compensation for biotic stressors. Received December 6, 1996; accepted March 5, 1997     

On the Relationship between the Activity of O-Methyltransferase and the Content of Lignin in Various Organs of Kidney Bean

The activity of O-methyltransferase (OMT) and the content of lignin in various organs of 12- to 14-day-old seedlings of kidney bean (Phaseolus vulgarisL., cv. Saksa) were determined. The epicotyl and hypocotyl were characterized by the highest OMT activity, and the leaves, by the lowest OMT activity. At the same time, the lignin content gradually increased in the following order: leaves < epicotyl < hypocotyl < roots. Thus, in kidney bean seedlings, there is no direct relationship between the OMT activity and the lignin content. It is suggested that lignin biosynthesis is limited by biosynthetic steps other than O-methylation of caffeic and 5-hydroxyferulic acids affected by OMT.     

Effects of Enhanced UV- B Radiation on Protein Metabolism of Bean Leaves

Bean ( Phaseolus vulgaris L. ) seedlings were grown in a greenhouse condition under UV-B (280 ~ 320 nm) radiation and an UV-B-free control condition. At early stage of bean growth, UV-B radiation(UV- BBE: 16 kJ·m-2·d-1 ) increased the synthetic rate of protein in bean leaves. UV-B radiation decreased the synthetic rate of protein and the content of soluble protein, increased the activities of caseolytic enzymes and the content of total amino acids in bean leaves at later growth stage. The results of SDS-PAGE indicated that UV-B radiation increased the contents of polypeptide in a range of 99 kD, 88 kD, 76 kD, 42 kD, 35 kD and 33 kD at the early stage, and increased that of 10 ~ 14 kD, 29 kD, 33 kD and 35 kD at later growth stage. It is suggested that the increase of these polypeptides is an adaptation response of plants to the enhanced UV-B radiation.     

Effect of Defoliation or Excision of Growing Axillary Shoots on the Composition of Labeled Products of Photosynthesis in the Leaves and Xylem Sap of Kidney Bean

The content of ¹⁴C in the products of photosynthesis of the source leaf and xylem sap was investigated in kidney bean (Phaseolus vulgaris L.) plants during the stage of mass tillering. ¹⁴C partition was measured a day after two-minute photoassimilation of ¹⁴CO₂ by an individual mature leaf located in the middle part of the shoot. The source-sink relations were disturbed by the excision of all mature leaves (except the source leaf) or all growing axillary shoots. The leaves or growing axillary shoots were excised 15 min after leaf feeding with ¹⁴C₂. A day later, in plants with excised growing axillary shoots, the content of ¹⁴C in the source leaf was by 18% higher and in those with removed leaves by 15% lower than in control plants. The next day after the excision of growing axillary shoots, radioactivity of the xylem sap increased; after defoliation, both the volume of the xylem sap and its specific radioactivity decreased. In the xylem sap of defoliated plants, the proportion of ¹⁴C in malate decreased more than six times, whereas the proportion of ¹⁴C in amino acids somewhat increased (1.5 times). In two days, the volume of the xylem sap exuded by treated plants became the same as in control plants and its radioactivity decreased almost by an order of magnitude but essentially did not differ in the both types of treatment. It is concluded that the processes occurring in the roots are governed by photosynthesis but its regulatory effect is limited by a photoperiod and largely depends on changes in the ratio between biosynthesis of amino acids in the roots and leaves.__________Translated from Fiziologiya Rastenii, Vol. 52, No. 4, 2005, pp. 518–521.Original Russian Text Copyright © 2005 by Chikov, Bakirova, Batasheva, Sergeeva.     

Pathogenic Variability of Isolates of Pseudocercospora griseola, the Cause of Common Bean Angular Leaf Spot, and its Implications for Resistance Breeding

The pathogenic variability was evaluated of 48 Pseudocercospora griseola isolates collected in the State of Minas Gerais, Brazil. Isolates were inoculated to a set of 12 international differential cultivars in a greenhouse. Ten pathotypes (55-15, 63-7, 63-15, 63-23, 63-25, 63-27, 63-31, 63-47, 63-55 and 63-63) were identified, showing the great pathogenic variability of this fungus in Minas Gerais State. Pathotypes 55-15, 63-15, 63-25 and 63-27 had not previously been reported in the State. Of the 48 isolates, all except pathotype 55-1547 induced a compatible reaction with all cultivars from the Andean group. Isolates were highly pathogenic in both Andean and Mesoamerican cultivars, thus being classified as Mesoamerican pathotypes. Pathotype 63-63 was the most widespread, and overcame the resistance genes present in all differential cultivars.     

Effect of Salt Stress on Carbon Metabolism and Bacteroid Respiration in Root Nodules of Common Bean (Phaseolus vulgaris L.)

Abstract: In the present work, we examined the effect of salinity on growth, N fixation and carbon metabolism in the nodule cytosol and bacteroids of Phaseolus vulgaris, and measured the O₂ consumption by bacteroids incubated with or without the addition of exogenous respiratory substrates. The aim was to ascertain whether the compounds that accumulate under salt stress can increase bacteroid respiration and whether this capacity changes in response to salinity in root nodules of Phaseolus vulgaris. The plants were grown in a controlled environment chamber, and 50, 100 mM or no NaCl (control) was added to the nutrient solution. Two harvests were made, at the vegetative growth period and at the beginning of the reproductive period. The enzyme activities in the nodule cytosol were reduced by the salt treatments, while in the bacteroid cytosol the enzyme activities increased at high salt concentrations at the first harvest and for ADH in all treatments. The data presented here confirm that succinate and malate are the preferred substrates for bacteroid respiration in common bean, but these bacteroids may also utilize glucose, either in control or under saline conditions. The addition of proline or lactate to the incubation medium significantly raised oxygen consumption in the bacteroids isolated from plants treated with salt.     

Chloroplasts Isolated from Kidney Bean Leaves Are Capable of Phenolic Compound Biosynthesis

The homogenate and chloroplast fractions isolated from the leaves of 10–14-day-old kidney-bean (Phaseolus vulgaris L.) seedlings were incubated with ¹⁴C-L-phenylalanine for 30 min in the light, and the incorporation of radioactivity into phenolic compounds was determined. Label incorporation into phenolic compounds of the homogenate and chloroplast fractions amounted to 15–17 and 4–5% of the introduced radioactivity, respectively. The chloroplasts were about an order of magnitude higher than the homogenate in the specific radioactivity of phenolic compounds. Chloroplasts contained four flavonol glycosides (kaempferol and quercetin aglycones), which were the major components of soluble phenolic compounds of leaves. It was concluded that kidney-bean leaf chloroplasts were capable of performing phenolic compound biosynthesis.     

Gas Exchange and Emission of Chlorophyll Fluorescence during the Monocycle of Rust, Angular Leaf Spot and Anthracnose on Bean Leaves as a Function of their Trophic Characteristics

Measurements related to gas exchange and chlorophyll fluorescence emission were taken from healthy and diseased bean leaves with rust, angular leaf spot, and anthracnose during lesion development for each disease. The experiments were performed at different temperatures of plant incubation, and using two bean cultivars. The main effect of temperature of plant incubation was in disease development. There was no significant difference between cultivars in relation to disease development and in magnitude of physiological alterations when disease severity was the same for each cultivar. These diseases reduced the net photosynthetic rate and increased the dark respiration of infected leaves after the appearance of visible symptoms and the differences between healthy and diseased leaves increased with disease development. The transpiration rate and stomatal conductance were stable during the monocycle of rust, however, these two variables decreased in leaves with angular leaf spot and anthracnose beginning with symptom appearance and continuing until lesion development was complete. Carboxylation resistance was probably the main factor related to reduction of photosynthetic rate of the apparently healthy area of leaves with rust and angular leaf spot. Reduction of the intercellular concentration of CO₂, due to higher stomatal resistance, was probably the main factor for leaves with anthracnose. Chlorophyll fluorescence assessments suggested that there was no change in electron transport capacity and generation of ATP and NADPH in apparently healthy areas of diseased leaves, but decreases in chlorophyll fluorescence emission occurred on visibly lesioned areas for all diseases. Minimal fluorescence was remarkably reduced in leaves with angular leaf spot. Maximal fluorescence and optimal quantum yield of photosystem II of leaves were reduced for all three diseases. Bean rust, caused by a biotrophic pathogen, induced less damage to the regulation mechanisms of the physiological processes of the remaining green area of diseased leaves than did bean angular leaf spot or anthracnose, caused by hemibiotrophic pathogens. The magnitude of photosynthesis reduction can be related to the host–pathogen trophic relationships.     

Cadmium-Induced Structural and Ultrastructural Changes in the Vascular System of Bush Bean Stems

The effects of a phytotoxic cadmium concentration (4.45 . 10^?5 M) on the structure and ultrastructure of bean plant stems were analysed by light (LM), transmission electron (TEM) and scanning electron microscopy (SEM). Cadmium significantly reduced both the number and the size of tracheary elements. Cadmium-induced electron dense depositions, which seemed to obstruct partially some xylem vessels, were found only in the later maturing tracheary elements (helical, scalariform or reticulate structure), but not in the annular structured early differentiated ones. Plants exposed to Cd showed less fiber development than the control plants. In the plants treated with Cd abnormally high amounts of calcium oxalate crystals were found in the paratracheary parenchyma cells of the bottom of the stems. The levels of soluble Ca²⁺ in the expressed stem sap of Cd-treated plants was significantly decreased, while substantial amounts of soluble Cd were detected. The probable mechanisms of the structural alterations observed are discussed.     

Retardation of Leaf Senescence by Triadimefon Treatment in Mung Bean Seedling

Treatment of triadimefon on detached leaves of mung bean (Phaseolus radiatus L. ) seedlings increased the levels of chlorophyll and soluble proteins. Declined activities of superoxide dismutase (SOD), peroxidase (POD), catalase (CAT) and ascorbate-peroxidase (AsA-POD) and contents of ascorbate (ASA) and glutathione (GSH) were observed during the senescence of detached young leaves. Triadimefon at concentration of 20 mg/L promoted the activities of POD, AsA-POD and levels of AsA and GSH, but had no effect on the activities of SOD and CAT. On the other hand, the levels of malondialdehyde (MDA) were increased and the increase of which was markedly negative correlated with the activities of POD, AsA-POD and with the contents of AsA and GSH during the senescence of leaves. MDA contents were decreased by triadimefon treatment. These resuits suggested that triadimefon retarded the senescence of leaves in mung bean seedlings in terms of enhancing the protective ability of plant tissues against membrane lipid peroxidation.     

Effect of Fermented Bean Paste on Serum Lipids in Rats Fed a Cholesterol-Free Diet

We examined the effects of fermented bean pastes derived from bean vinegar by-products on serum cholesterol in rats. The rats were fed boiled paste from adzuki (A), kintoki (K), or tebou (T), or fermented paste from adzuki (AP), kintoki (KP), or tebou (TP) for 4 weeks. The serum non-high-density lipoprotein (HDL) cholesterol levels in all the experimental groups, except for A group, were significantly lower than in the control (CN) group. Likewise, the serum triglyceride levels in K and all the fermented bean groups were significantly lower than in the CN group. The levels of hepatic 3-hydroxy-3-methylglutaryl-CoA (HMG-CoA) reductase mRNA in all the experimental groups except for A were significantly lower than in the CN group. These findings indicate that fermented bean pastes also suppress cholesterol synthesis, resulting in a reduced serum cholesterol concentration. These effects might be related not only to the resistant starch but also to the protein or peptide in the fermented bean paste.     

The Phototropic Pulvinus of Bean Phaseolus vulgaris L. - Functional Features

Abstract: The laminar pulvinus of bean ( Phaseolus vulgaris L.) is a highly specialized organ for reorienting the lamina, and exhibits positive phototropic curvature. Structural and ultrastructural features of the pulvinus were studied to determine their possible role in its phototropic response. The vascular tissue forms a flexible, relatively inextensible central core enclosed by a starch sheath and surrounded by a multi-layered motor tissue. Phototropic curvature is a result of opposite anisotropic changes in volume of the cells in the exposed and opposite sectors of the motor tissue. Radial inflexibility of the epidermis and axial plasticity constrain these changes to the pulvinar axis. Anisotropic changes in volume of motor cells reduce the osmotic work involved. Motor cells exhibit features that are associated with high synthetic activity: thick cytoplasm with numerous ribosomes, polysomes, RER and SER, well-developed mitochondria and a large nucleus. Numerous, well-developed chloroplasts, with little starch, are increasingly abundant toward the periphery. The intercellular system is limited and partially filled with matrix. Stomata are absent and the motor tissue lacks vascularization. These features support the suggestion that the primary role of the chloroplasts in the photonastic response is photophosphorylation and photosynthetic electron transport (Koller et al., 1995^[339]).     

菜豆叶片衰老期间叶绿体被膜膜脂与脂肪酸组分的变化

菜豆叶片叶绿体总脂和被膜膜脂中均含有单半乳糖甘油二脂和双半乳糖甘油二脂,在整个衰老期间两种糖脂的比值变化不大。叶绿体总脂中含有5种磷脂,脂肪酸以不饱和的亚麻酸为主,而被膜膜脂中仅含磷脂酰胆碱和磷脂酰甘油,脂肪酸以饱和的棕榈酸为主,不饱和亚油酸为次。叶片衰老过程中被膜所含两种磷脂比值明显降低,脂肪酸的不饱和指数也因亚麻酸相对含量显著减少、棕榈酸相对含量增加而降低。     

Bean (Phaseolus vulgaris L.) protoplasts as a model system to study the expression and stability of recombinant seed proteins

A suitable protocol for the transient expression of seed protein genes in protoplasts derived from cell suspension cultures of common bean has been established. Preliminary analyses of cultures to verify the synthesis of phaseolin – actively accumulated by the starting tissue, the developing cotyledon – showed that the protein was no longer synthesised after 5 days of culture. Transient expression of a phaseolin sequence, driven by a constitutive promoter, resulted in the accumulation of the correctly glycosylated and assembled protein. This system, when compared to tobacco protoplasts, largely avoids phaseolin fragmentation and the presence of contaminant polypeptides in the immunoprecipitates. Therefore, bean protoplasts are a good system to study the expression of wild-type as well as in-vitro-modified bean seed proteins. Received: 26 November 1996 / Revision received: 10 February 1997 / Accepted: 15 February 1997